A linear neural circuit for light avoidance in Drosophila larvae

Abstract

Understanding how neural circuits underlie behaviour is challenging even in the era of the connectome because it requires a combined approach encompassing anatomical and functional analyses. This is exemplified in studying the circuit underlying the light-avoidance behaviour displayed by the larvae of the fruit fly Drosophila melanogaster. While this behaviour is robust and the nervous system relatively simple, only bits and pieces of the circuit have been delineated¹. Indeed, some studies resulted in contradicting conclusions regarding the contributions of various neuronal types to this behaviour^2,3. Here we devise trans-Tango MkII, a new version of the transsynaptic circuit tracing and manipulation tool trans-Tango⁴. We implement trans-Tango MkII in anatomical tracing and combine it with circuit epistasis analysis. We use neuronal inhibition to test necessity of particular neuronal types for light-avoidance. We complement these experiments by selective neuronal activation to examine sufficiency in rescuing light-avoidance deficiencies exhibited by photoreceptor mutants. Together, our studies reveal a four-order, linear circuit for light-avoidance behaviour connecting the light-detecting photoreceptors with a pair of neuroendocrine cells via two types of clock neurons. Our combined approach could be readily expanded to other larval circuits. Further, this strategy provides the framework for studying more complex nervous systems and behaviours.